import openvoronoi as ovd
import ovdvtk
import time
import vtk
import math

import offset2vtk
import truetypetracer as ttt  # https://github.com/aewallin/truetype-tracer


def insert_polygon_points(vd, polygon):
    pts = []
    for p in polygon:
        pts.append(ovd.Point(p[0], p[1]))
    id_list = []
    print "inserting ", len(pts), " point-sites:"
    m = 0
    for p in pts:
        id_list.append(vd.addVertexSite(p))
        print " ", m, " added vertex ", id_list[len(id_list) - 1]
        m = m + 1
    return id_list


def insert_polygon_segments(vd, id_list):
    j = 0
    print "inserting ", len(id_list), " line-segments:"
    for n in range(len(id_list)):
        n_nxt = n + 1
        if n == (len(id_list) - 1):
            n_nxt = 0
        print " ", j, "inserting segment ", id_list[n], " - ", id_list[n_nxt]
        vd.addLineSite(id_list[n], id_list[n_nxt])
        j = j + 1


def insert_many_polygons(vd, segs):
    polygon_ids = []
    t_before = time.time()
    for poly in segs:
        poly_id = insert_polygon_points(vd, poly)
        polygon_ids.append(poly_id)
    t_after = time.time()
    pt_time = t_after - t_before

    t_before = time.time()
    for ids in polygon_ids:
        insert_polygon_segments(vd, ids)

    t_after = time.time()
    seg_time = t_after - t_before

    return [pt_time, seg_time]


def translate(segs, x, y):
    out = []
    for seg in segs:
        seg2 = []
        for p in seg:
            p2 = []
            p2.append(p[0] + x)
            p2.append(p[1] + y)
            seg2.append(p2)
        out.append(seg2)
    return out


def ttt_segments(text, scale):
    wr = ttt.SEG_Writer()
    wr.arc = False
    wr.conic = False
    wr.cubic = False

    wr.conic_biarc_subdivision = 10  # this has no effect?
    wr.conic_line_subdivision = 50  # this increases nr of points
    wr.cubic_biarc_subdivision = 10  # no effect?
    wr.cubic_line_subdivision = 10  # no effect?
    wr.setFont(3)

    wr.scale = float(1) / float(scale)
    ttt.ttt(text, wr)
    segs = wr.get_segments()
    return segs


def modify_segments(segs):
    segs_mod = []
    for seg in segs:
        first = seg[0]
        last = seg[len(seg) - 1]
        assert (first[0] == last[0] and first[1] == last[1])
        seg.pop()
        seg.reverse()  # to get interior or exterior offsets
        segs_mod.append(seg)
        # drawSegment(myscreen, seg)
    return segs_mod


if __name__ == "__main__":
    # w=2500 # screen resolution for big screens
    # h=1500

    # w=1920
    # h=1080
    w = 1024
    h = 1024
    myscreen = ovdvtk.VTKScreen(width=w, height=h)  # a VTK window for drawing
    ovdvtk.drawOCLtext(myscreen, rev_text=ovd.version())  # the OpenVoronoi text, revision, and date

    scale = 1
    myscreen.render()

    far = 1
    camPos = far
    zmult = 3
    # camPos/float(1000)
    myscreen.camera.SetPosition(0, -camPos / float(1000), zmult * camPos)
    myscreen.camera.SetClippingRange(-(zmult + 1) * camPos, (zmult + 1) * camPos)
    myscreen.camera.SetFocalPoint(0.0, 0, 0)

    vd = ovd.VoronoiDiagram(far, 120)
    print ovd.version()

    # for vtk visualization
    vod = ovdvtk.VD(myscreen, vd, float(scale), textscale=0.01, vertexradius=0.003)
    # these actions on the vod object control how the VD is drawn using VTK
    vod.drawFarCircle()
    vod.textScale = 0.02
    vod.vertexRadius = 0.0031
    vod.drawVertices = 0
    vod.drawVertexIndex = 0
    vod.drawGenerators = 0
    vod.offsetEdges = 0  # for debug. a bool flag to set null-edge drawing on/off. use together with setEdgeOffset()
    vd.setEdgeOffset(0.05)  # for debug. a non-zero value will draw null-edges as circular arcs
    # null-edges are an internal openvoronoi construction to avoid high-degree vertices in the VD-graph
    # they are not relevant for upstream or downstream algorithms

    print "all sites inserted. "
    print "VD check: ", vd.check()

    # segments from ttt
    segs = ttt_segments("H", 30000)
    segs = translate(segs, -0.06, -0.05)
    segs = modify_segments(segs)

    # a box around the character
    box = 0.1
    p0 = [-box, -box]
    p1 = [box, -box]
    p2 = [box, box]
    p3 = [-box, box]
    seg0 = [p3, p2, p1, p0]
    segs.append(seg0)

    times = insert_many_polygons(vd, segs)

    pi = ovd.PolygonInterior(False)
    vd.filter_graph(pi)

    of = ovd.Offset(vd.getGraph())  # pass the created graph to the Offset class
    of.str()  # text output, for debug
    dists = [0.004 * x for x in range(1, 15)]
    ofs_loops = []
    ofsl = []
    for d in dists:
        d_offsets = of.offset(d)
        if len(d_offsets) != 0:
            ofs_loops.extend(d_offsets)  # compute offset at d, and add to loop-list
            ofsl.extend(of.offset_loop_list(d))
    # print ofsl

    sorter = ovd.OffsetSorter(vd.getGraph())
    for loop in ofsl:
        sorter.add_loop(loop)

    sorter.sort_loops()
    # this generates a graph test.dot
    # to generate a png image run
    #  dot -Tpng test.dot > test.png
    ofs_loops2 = sorter.get_loops()
    print "number of loops= ", len(ofs_loops2)

    offset2vtk.drawOffsets(myscreen, ofs_loops2)  # draw the generated offsets

    """
    for loop in ofs_loops:
        first_vert=loop[0]
        print "loop at dist=", first_vert[2], " with ",len(loop)," vertices:"
        for v in loop[1:]:
            print " face ",v[4]
    """
    vod.setVDText2(times)
    vod.setAll()
    print "PYTHON All DONE."
    myscreen.render()
    myscreen.iren.Start()
